Ractopamine Hydrochloride and Estradiol + Trenbolone Acetate Implants Alter Myogenic mRNA, β-Adrenergic Receptors, and Blood Metabolites

动物科学期刊(英文) Pub Date : 2020-05-18 DOI:10.4236/ojas.2020.103028

T. L. Harris, Z. Smith, F. Ribeiro, M. Jennings, G. Vogel, B. Johnson

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引用次数: 3

Abstract

Two commonly used growth promotants in the United States beef industry are β-agonists and anabolic steroid hormones. Each has been shown to increase lean muscle deposition in cattle provided treatments of each growth technology, but much is still unknown of how steroidal implants and β-agonists work in combination. It was our goal to determine the effect of implant strategy and β-agonist administration in beef feedlot heifers (n = 264). A 3 × 2 factorial randomized complete block design was used with 2 levels of OPT and 3 different durations of terminal implant (TI) windows for a total of 6 treatment groups with 9 replications. Terminal implants (20 mg estradiol/200 mg trenbolone acetate implant, Component TE-200) were provided to heifers 140 d from slaughter (TI140), 100 d from slaughter (TI100), or 60 d from slaughter (TI60). Animals receiving the later two TI being first implanted on day 0 (8 mg estradiol/80 mg trenbolone acetate implant, Component TE-IH). The second treatment of the cattle received was the orally active beta adrenergic agonist, ractopamine-hydrochloride (RH) in the form of Optaflexx®(OPT; 0 (NO) or 200 (YES) mg/hd·d-1) over the final 28 days of the trial. Thirty animals were subjected to longissimus muscle (LM) biopsies on d 0, 40, 80, 112, and at slaughter on d 140 to view mRNA levels of myogenic related genes and protein quantities of the β1-adrenergic receptor (β1 AR) and β2-adrenergic receptor (β2 AR). On the same days, blood samples were taken from 108 animals to assess changes in plasma blood urea nitrogen (BUN), non-esterified fatty acids (NEFA) and progesterone due to treatments. Relative mRNA levels of myosin heavy chain IIX (MHC IIX), AMPKα, and IGF-I were increased (P P = 0.09) due to OPT. An interaction between TI d and OPT administration caused an increase (P β2 AR was decreased (P β1 AR protein intensity tended to be lower (P P P β-adrenergic receptors, and blood metabolites in finishing beef heifers.

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盐酸Ractopamine和雌二醇+醋酸Trenbolone植入物改变肌源性信使核糖核酸、β-肾上腺素受体和血液代谢产物

两种常用的生长促进剂在美国牛肉行业是β-激动剂和合成代谢类固醇激素。每种生长技术都能增加牛的瘦肌肉沉积，但甾体植入物和β激动剂如何结合使用仍不清楚。我们的目标是确定植入策略和β-激动剂给药对肉牛饲养场小牛的影响(n = 264)。采用3 × 2因子随机完全区组设计，采用2个OPT水平和3个不同时间的末段植入(TI)窗口，共6个治疗组，共9个重复。在犊牛屠宰后140 d (TI140)、100 d (TI100)或60 d (TI60)分别给予末端植入物(雌二醇20 mg /醋酸trenbolone 200 mg植入物，TE-200组分)。接受后两种TI的动物在第0天首次植入(8 mg雌二醇/80 mg醋酸trenbolone植入物，TE-IH成分)。牛接受的第二次治疗是口服活性β肾上腺素能激动剂盐酸莱克多巴胺(RH)，其形式为Optaflexx®(OPT;0 (NO)或200 (YES) mg/hd·d-1)在试验的最后28天。30只动物分别在第0、40、80、112天和第140天屠宰时进行最长肌(LM)活检，观察成肌相关基因的mRNA水平和β1-肾上腺素能受体(β1 AR)和β2-肾上腺素能受体(β2 AR)的蛋白含量。同一天，从108只动物身上采集血样，评估血浆尿素氮(BUN)、非酯化脂肪酸(NEFA)和黄体酮在处理后的变化。肌球蛋白重链IIX (MHC IIX)、AMPKα和IGF-I的相对mRNA水平因OPT而升高(P P = 0.09)。TI和OPT的相互作用导致育肥牛P β2 AR升高(P β2 AR降低)(P β1 AR蛋白强度趋于降低)(P P P β-肾上腺素能受体)和血液代谢产物。

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动物科学期刊(英文)

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